Gas lift system and apparatus therefor



March 31, 1953 ,A J. ZABA 2,633,086

GAS LIFT SYSTEM AND APPARATUS THEREFOR l Filed June 19. 1947 '7 Sheets-Sheet 1 FW' 2 Joseph zba,

IN V EN TOR.

, .BYWMW A TTRNEY ...a 2 10 R. m .t a0 R w, ZW m l ,QW T s S d 2 .m l WI A u a @I R 7 3 m O F E 1 m v1 Y I B T A Am B.M A Zw A J m w w. W.. r u w fd March 3l, 1953 Flled June 19, 1947 Pressure March 3l, 1953 J. zABA 2,633,086

` GAS 'L11-"T SYSTEM AND APPARATUS THEREFOR Filed June 19, 1947 7 sheets-sheet 4 @jc/f. fd Fiy- 13 Joseph Z ab ai I P/'ESFU IN V EN TOR.

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Josepb Zb INVENTOR BY ATToRNm/ 7 Sheets-*Sheet 5 J. ZABA GAS LIFT SYSTEM AND APPARATUS THEREFOR Filed June 19. 1947 March 311, 1953 ssare March 31, 1953 J. zABA 2,633,086

GAS LIFT SYSTEM AND APPARATUS THEREFOR Filed June 19, 1947 A 7 Sheets-Sheet 6 235 233 M6" 24 7 w/-MQ 243 -ZZ8 a pressure Fey 20 Joie Cyce Z d f BY man Fig. 21 ATTORNEY J. ZAB'A GAS, LIFT SYSTEM AND APPARATUS THEREFOR March 31, 1953 7 Sheets-Sheet 7 Filed June 19, 1947 o w l 3 f /////V///////// f/ l 2 Y Mgg Joseph Z alia,"

INVENTOR.

Fig, 24 1z=ssune e ATTR/VEY Patentedl Mar. 31, 1953 UINIITED STATES PATENT OFFICE GAS LIFT SYSTEM AN-D APPARATUS THEREFOR joseph. Zaba, Houston, Tex., assigner to McEvoy Texas" Company, Houston, Tex., a corporation of" i Application Ju'lie 19, 194'?,l Serial No. 755,603

This invention pertains primarily to gas lifts for raising petroleum fluidsfrom a IWell-` and more particularly to intermittently operating' gas lifts in'. which the oilv is lifted in slugs lwith* the gas acting behind the. slug. as against. a piston,y which mode of operation is tobe: distinguished from that of the type'- of gas lift which operates by aerating the oil', although portions of. the inventionV are applicable to lifts generally. Some of the novel elements ofv the invention arev not limited. to thefleld of gas lifts buty are of general application including such broad fields as: that. of regulating devices.

The principal object ofthe invention is to im.- prove the. eiiiciency of operationof gas` lifts so as to obtain maximum. production.

A further objectof the: invention is to reduce the quantity of gas? needed tol obtain. a given rate of production.

Another object of: thel invention isv to improve lthe gas-oil ratio and maintain it substantially constant.

Still another object of: theinvention isto make thequantity of gast use'ci` adjustable from thesurface ofthe ground.

. Yet another' object oftheinvention"` is to reduce toaminimum4 the number of" pieces of. bottom hole equipment neededC fora gas: lift and toslmplify the construction-thereof.

Another object? of: the" invention ist to makex it possibleto` remove ther-bottom hole equipment.` of theparticular gas-flifti according to theV invention Without the necessity' ofp'ulling the tubing.

Another object. of' the; invention is` to" simplify the construction of: theasurfacecontrolsand to eliminate'. the necessity'. forl a clock'. mechanism'.

-A further object.4 of thev invention. is to1sim plify the over allconstruction of their gasV liftrap'- paratus particularly'b'y eliminating the need for any'- macaroni strings, wire lines, reciprocable tubing or other cumbersome equipment for op'- erating the subsurface valve mechanism from the'vsurface.

Another. object' of the invention is' te provide a single type of gas lift that. isf'adaptable" to: all types of. wellshighlandlow productivity and high and` low pressure.

Another objectof thexinvention` is 4to provide a gas" lift.that.is.= strong.: and durable and` will not require frequent repair even in` wells producing large proportionsy of saltwater, sand, and other corrosive and abrasive1substances` along with the petroleum fluids.

By way of? introductiom itsm'awbe said` that a typical embodiment".oiitheunvention comprises-a valve mechanism or means at the botom of the 47 Claims. (Cl. 16S-#231) hole which is controlled by a well fluid responsive deviceto open communication betweennthe tubing and the casing annulus when a predetermined quantity of fluid has accumulatedvand a. valve mechanism or means at the surface vof the ground wh-ichV is controlled in response to the changed condition of the gas in the annulus produced by openingl of the bottom hole valve mechanism to opencommunication between the gas supply and the annulusV after the subsurface valve mechanism hasV opened and to close comrnunication` therebetween after a predetermined quantity of gas has been-admitted to the annulus sunicient to makey up the amount. needed to raise the well fluid to the surface, the subsurface valve mechanism acting in responsel to changes in pressure'of the gas,v in the annulus to close communication between the casing annulusand tubing at a time prior tothe expulsion of the Well uid from the tubing when thereissuflicient gas beneath the wellv fluid'.v to lift it tothe surface by expansion ofthe gas.

The principal advantages of the ,inventionk as just set forth lie in the fact that the gas is not admitted to the wellfluid. until exactly the predetermined amount of` fluid hasy accumulated so that.r proper submergence will be hadV and so that the amount of fiuidWill notbe too great for the `gas to lift, While at the same' time the. gas supply to the well fluid is cut. off. prior to complete expulsionI of thevwellfiiuid at just the right time so thatnomore gas is used than is needed, the amount ofr gas` admitted. being adjustable from the surface so.` that the exact quantity can be determined by trial. after the apparatus has been installed. Y

The chief problem-.l involved in the attainment of the stated obects lies in the constructionvr of a subsurface valve mechanism thatA will open in response to the accumulation of the desired quantityof well fluidand yet will close before the welliiuid has been expelled. Prior systems are known` utiliainvg wwell4 fluid responsive valvesl to admit. gasto the well uidtoraise thewell fluid but these have.- beenf. unsatisfactory because admission-of gasto the. well` fluid. maintains the pressure in the passage con-taining the well" iiuid atthe point wherethe well uidresponsifve valve is klocated even after the: well fluid has` left'. the valvevsothat the valvev remains open the same as ifwell fluid-were there. untilthe wellliiuid is expelled at: the-top of the well,v lettingV the. gas pressure` drop.; With such` systemsv the gas-oil ratio isnotA adjustablen and.r is fxedf atan` un.-

: economicalfpointi Other prior systems are known in which' the subsurface valves are controlled from the surface so that the flow of gas to the well fluid eduction passage can be cut off at any time. In these systems it is possible to close the subsurface valves at a predetermined time when enough gas has been admitted to the well fluid so that expansion of the gas will ultimately lift the well fluid to the surface, thereby avoiding waste of gas. However, in these systems the subsurface valve mechanisms are not automatically operated to admit gas to the well fluid when a predetermined quantity has accumulated. The operator of the system must estimate when such quantity of fluid probably will have accumulated,.based on pre-V the provision of a subsurface valve means or mechanism having a principal means for controlling communicationthrough a passage between the gas induction passage and the well fluid eduction passage, one means responsive vover a limited range to conditions in the well fluid eduction passage for operating the principal means to open communication between the two passages, and another-means responsive to conditions in the gas induction passage for operating the principal means to close communication between the two passages, the means responsive to conditions in the induction passage being capable of operating the principal means to closed position independently of the position of the means responsive to conditions in the eduction passage, the limited range of response of the means responsive to conditions in the eduction tube preventing it from 'blocking operation of the means responsive to conditions in the gas induction passage which might otherwise occur due to the eect on conditions in the eduction passage produced by changes in conditions in the induction `passage when communication is open between the two passages.

In one form of the invention two valves actuated by separate control devices are used for the subsurface valve mechanism, one valve operating as a pilot valve responsive to the well fluid to cause changes in gas pressure to open the main subsurface gas valve which is later closed by gas pressure changes caused by operation of the surface valve mechanism. Since both -valves operate each time a load is carried to the surface, they are subject to wear and after having been in use for some time may have to be repaired or replaced. For this reason it is desirable that the subsurface valve mechanism be removable without pulling the tubing. While it is possible to make both the valves of the two valve system removable it is much less dicult to make a single valve removable. Accordingly, in another form of the invention but a single valve is used provided with two control means, one responsive to conditions in the well fluid eduction passage and the other responsive to conditions in the gas induction passage.

It is one of the objects of the invention to simplify the construction of a single valve dual control device of the type just described. This has been achieved by means of a novel element hereinafter referred to as a double bellows. Briefly, the double bellows valve construction comprises two sealed bellows placed with their` interiors in communication with each other and having gas at a predetermined pressure inside with the exterior of one bellows exposed to one force and the exteriorof the other exposed to another force, and a valve connected to one of the bellows. Changes in the force acting on the bellows connected to the valve will operate the valve directly, while changes in the force acting on the other bellows will indirectly operate Ithe valve by changing the volume of the combined space inside the two bellows, thereby changing the gas pressure and causing the bellows connected to the valve to move to operate the valve. Instead of filling the interior of the bellows with gas, other elastic means of low force-deformation ratio such as a helical spring or a piece of `resilient rubber could be'placed inside the two 4:bellows between their'end'walls so as to transmit force non-positively from one to the other. While this double bellows construction is peculiarly suited to the purpose of operating an intermitter valve for a gas lift it can also be used for other purposes and in other elds wherever it is desired to have a device positively responsive to one force and non-positively responsive to another. The thing to be operated need not be a valve but could be any member which it is desired to move.

Returning to consideration of the system of the invention as a whole, three principal forms of the invention will be described, classified according to the cycle of operation as indicated by changes in the gas pressure in the gas induction passage. In the first form of the system, initial operation of the subsurface gas valve mechanism in response to accumulation of the predetermined quantity of well fluid opens communication through a passage between the gas induction and fluid eduction passages causing a change in the condition of the gas in the gas induction passage. This change of condition of the gas, for example a drop in the static pressure or an increase in the rate of ow (kinetic change) ac- `tuates the surface valve mechanism to open communication through a passage between the source of gas under pressure and the gas induction passage which causes the gas pressure in the gas induction passage to rise, lthe rate of admission of gas at the surface being greater than the rate of exhaust at the bottom. The gas pressure continues .to rise until after a predetermined quantity of gas has been admitted the surface valve mechanism closes. At the moment of closing of the surface valve mechanism the gas pressure in the gas induction line will be considerably higher than the pressure at the beginning of the cycle. The gas Apressure will then start to fall again and will continue to fall until the starting pressure is reached, at which point the subsurface valve mechanism closes, thus completing the cycle.

A second form of the system operates on a cycle similar to the first cycle except that at the end of the cycle the gas pressure must drop below the starting pressure to close the subsurface valve mechanism. The surface valve mechanism is always open to a limited degree Whenever the gas pressure in the gas induction line is below the starting pressure and the gas pressure returns slowly to the starting pressure after the subsurface valve mechanism has closed.v

aaneen- Y A @hind form f. the mention Operates. on a 1cyclewhich starts the same as the rst cycle in that accumulation of well uid opens the subsurface valve mechanism. This causes a drop in pressure in the gas induction line but the surface controls do not respond to the change in gas, pressure, until there has been a considerable pressure drop and in the meantime a'considerable` quantity of gas has been admitted to the well fluid. The surface valve mechanism finally responds to admit gas to the gas induction passage and rapidly bring the pressure back to the starting pressure and above. When the pressure is aI certain amount above the starting pressure the subsurfacevalve mechanism closes and at a slightly` higher pressure the surface valve mecha- .IiiSIn closes communication between the supply of gas under pressure and the gas induction passage. A t all times when the pressure in the gas induction passage is above the starting point the surface valve mechanism opens a limited cornmunication between the `gas induction passage and the. low pressure side of the Supply of gas under pressure thereby bringing the gas pressure back to the starting point after the surface valve` mechanism has closed communication to the high pressure side of the supply. y

The fluid produced by the well may be a mixture of petroleum solids, liquids, and gases and other materials such as water, sand and basic sediment. Predominently it will be in liquid form. 'I o further facilitate description of the invention this material will'be referred to hereinafter as a liquid, or moresimply, as oil. In both the speciiicatin and the claims however, these terms are t0 be understoodv to include any of the usual products of a well including Water wells as well as petroleum wells except wherethe context otherwise indicates. I

In all forms of the invention it is required that there be two passages from the top of the well to the bottom, one constituting the gas induction passage for conducting gas to the bottom of the well-andthe other constituting the oil eduction passage fory conducting oil to the surface. In the yusual well the'hole will be lined with casing and a, string of tubing will be run inside the casing. In such case the tubing will` usually be the eduction passage for the oil and the annulus between the tubing and casing will be the gas induction passage. For convenience hereinafter this usual arrangement will be referred to for the purpose of facilitating description of the invention but it is to be understoody that by mere interchange of position of the elements the gas can be admitted through the tubing and the well fluid produced through the annulus. Also, a greater or lesser number of strings of pipe can be used' one inside the other as long as two passages are povided for the gas and wellfluid.

Another feature common to all forms of the invention is a seal between the tubing and casing to prevent gas from blowing down around the end of the tubing and back up through the tubing around the well. In high bottom hole pressure wells this seal may be formed by the oil itself rising beyond the end of the tubing. In such case the oil pressure will befhigher than the lift pressure. In the more usual arrangement however the seal will be inthe form of a packer expanded between the tubing and. casing. `Before the packer is set all oil wi1`1- bey blown out of the annuius so that after the packer is set the annulus above the packer will 4be purely a gas passage. The use of a packer or 121.1@s highest extent of rise oi oil ,in the. annulus is exactly limited so that the gas responsive subsurface valve mechanism can be placed without, fear that it will be blocked by being covered withk oil as might occur in a packerless system. Also, the volume of the gas space inthe annulus` is more accurately fixed so that more exact determination can be made of the quantity of gas admitted to the annulus. K

A furtherelement shown in connection with all yforms of the invention is a check valve at the bottom of the oil tubing. The principal purpose of thisvalve is to keep thegas pressure off the formation when the gas is admitted to the tubing. This is usually desirable to preventback ow of the oil in the formation. However in the case. of a packerless system such a check valve would be unnecessary. Also, according to some authorities some wells benefit by intermittent application of back pressure in4 which cases the check valve could be omitted also. l k

In most intermittent systems it is desirable to operate in such a way that a head of oil equal to that which, the bottom hole pressure can support is never allowed to build up. Instead, the head of oil is initially blown off to a low level and thereafter whenever a barrel or so of oil accumulates it is blown off. In this manner the back pressure on the formation is reduced during the period the oil is accumulating so that it may flow 'in more rapidly. To achieve the initial reduction in the head of oil without utilizing a gas pressure excessively greater than that required to lift the oil during normal operation of the system, resort is had to a system of stage lift utilizing valves spaced along the tubing at intervals to admit gas to the tubing at successively lower levels, blowing off successive slugs of oil of the short length between each pair of valves. The valves are knownas kick off, or unloading valves. A great variety of such valves are known and are suitable for use ancillary to the system of the invention. However for the vpurpose of illustration only two types of such valves will be shown, these two types being peculiarly well suited for usewith the intermitter system of the invention.

Onetype of .unloading valve especially suited for use with the system vof the invention is described in United States Reissue Patent Number 21,998, granted January 6, 19,42, to Maurice B. Thomas, .and in United States Patent Number 2,317,121, also granted to Maurice B. Thomas, April 20, 1943. The valve of these patents operates in response to changes in the diiference between the pressures above and below a column of liquid caused by changes in the specific gravity of the fluidY in the tubing. Thus, when there is gas or aerated oil in the tubing which is of lower specic gravity than the liquid of the valve, the valve is closed, But when dead oil is in the tubing above and below the liquid of the valve, such dead oil having a higher specific gravity than the liquid of the valve, the valve will open. The valve is thus in reality a float operated valve using alight liquid as the iioat body and will hereafter be referred to as a float valve.

l Another type of unloading valve that will be Vshown in connection with the system of the invention comprises a bellows actuated valve. The bellows may be expanded by a spring inside or by a charge of gassealed therein. In either casethe valve is opened by an increase in the gas pressure outside the bellows. Descriptions of valves of this type 'are to be found in United StatesoPatents similar nxedseal hasa further advantageinthat Number 1,803,837-J granted May 5'J 1931;,v to Mark 7 P. Burke, and Number 2,339,487, granted January 18, 1944, to William R. King.

For a detailed description of several preferred embodiments of my invention illustrating it in three principal forms and showing a number of modifications thereof, reference will now be had to the accompanying drawings in which:

Figure 1 is an elevational view of a Well partly in section and partly schematic, showing a gas lift system according to the invention operating on the rst described cycle.

Figure 2 is a sectional detail of a portion of the bottom hole valve mechanism.

Figure 3 is a graph'showing the changes in annulus gas pressure plotted as ordinates against time as abscissas.

Figure 4 is an elevational view of a Well, partly in section and partly schematic, showing a modied form of a gas lift according to the invention operating on the first described cycle.

Figure 5 is a sectional detail of a portion of the surface valve mechanism.

Figure 6 is a graph similar to Figure 3 showing the variation in gas pressure in the system of Figure 4.

Figure 'I is a sectional detail of a modified form of subsurface valve mechanism to be used with the general system shown in Figure 4. l

Figure 8 is a section taken on the line 8 3 of Figure '7.

Figure 9 is a sectional detail of a subsurface valve mechanism similar to that of Figure '7 but slightly modified.

Figure l is a sectional detail showing a device for holding the subsurface valve mechanism in place.

Figure 11 is a graph similar to Figure 3 showing the annulus gas variations in systems similar to that shown in Figure 4 except modified by incorporation of a subsurface valve mechanism of the type shown in Figures 7 and 9.

Figure 12 is an elevation of a well, partly in section and partly schematic, showing another modified form of the gas lift system according to the invention operating on the first described cycle.

Figure 13 is a sectional detail of the subsurface valve mechanism used in the system shown in Figure 12.

Figure 14 is a graph similar to that of Figure 3 showing the annulus gas pressure variations in the system of Figure l2.

Figure l is an elevation of a well, partly in section and partly schematic, showing another form of the gas lift system according to the invention operating on the second described cycle.

Figure 16 is a sectional detail of the subsurface valve mechanism used in the system shown in Figure l5.

Figure 17 is a graph similar to that of Figure 3 showing the annulus gas pressure variations in the system of Figure 15.

Figure 18 is an elevation of a well, partly in section and partly schematic, showing a modified form of gas lift system according to the invention operating on the second described cycle.

Figure 19 is a diagram showing various positions of a portion of the surface valve mechanism during a cycle of operation of the system of Figure 18.

Figure 20 is a sectional detail of the subsurface valve mechanism used in the system of Figure 18.

Figure 21 is a graph similar to that of Figure 3 showing the variations in the annulus gas pressure of the system of Figure 18.

Figure 22 is an elevation of a well, partly in section and partly schematic, showing still another form of the gas lift system according to the invention operating on the third described cycle.

i' Figure 23 is a sectional detail of the subsurface valve mechanism for the system shown in Figure 21.

Figure 24 is a graph similar to that of Figure 3 showing the variations in annulus gas pressure in the system shown in Figure 21.

Referring to Figure 1 there is shown a well lined with a casing I0 and provided with an oil eduction tubing I I. The casing I0 extends to the bottom of the hole and is cemented as shown at I2. A portion of the casing opposite the producing formation I 3 is perforated as indicated at I4. The top of the casing is closed and sealed to the tubing as shown at I5. Any suitable type of casing head construction may be used for the purpose. The casing head is provided with an opening connected to the gas supply line I6.

The tubing extends through the casing head to a point near the bottom of the hole opposite the producing formation. The bottom end of the tubing is closed as shown at I'I. The portion of the tubing just above the closed end is perforated as indicated at I8. Somewhat above the level of the producing formation there is a packer I9 sealing between the tubing and casing. Starting a few feet above the level of the packer and continuingfor perhaps several hundred feet the tubing may be of a somewhat larger diameter to provide an accumulation chamber as indicated at 20. Above the accumulation chamber at intervals the tubing may be provided with one or more unloading valves, preferably the iioat type previously described and .shown at 2|. The top of the tubing is connected to an oil line 22 through a valve 23.

The surface valve mechanism comprises a main valve 30 in the gas line I6. Valve 30 is a motor valve of the diaphragm actuated type. The valve stem 3| is connected to the diaphragm 32. The diaphragm and valve stem are normally urged upwardly by a spring 33 to open the valve. Gas under pressure admitted through conduit 34 will close the valve. When the supply of gas to conduit 34 is shut on" or reduced the gas above diaphragm 32 will exhaust through port 35 allowing the spring 33 to open the valve.

Gas Afor operating motor valve 30 may be taken from any suitable source, but preferably is obtained from the main gas line I6 through conduit 36. A filter and drip shown at 31 is provided in the conduit 36 for cleaning the gas. A pair of series connected gas pressure regulators 38 and 39 are also connected in the conduit 36 for reducing the pressure from that in the gas line I6 to a pressure suitable for operation of the motor valve 30.v Connecting the conduit 36 and conduit 34 there is a hollow body 40 having a restricted portion `4I and an exhaust port 42. For controlling the exhaust port 42 there is a flapper valve 43 pivotally mounted at 44 on the end of the Bourdon tube 45. The opposite end of the Bourdon tube is fixed by a clamp 46 and is connected by conduit 41 to the gas supply line I 6 on the downstream side of valve 30. In the position shown the Bourdon tube is expanded so that the pivot point 44 is toward the extreme left of its travel. In this position the adjustably mounted permanent magnet y48 attracts the magnetic stem 43 of the flapper valve to the right so that the apper valve 43`closes the exhaust port 42. Upon assenso S a drop in pressurein the casing annulus of the well the Bourdon tube will be contracted moving the pivot point 44 tothe right. Fulcrum 50 prevents the center portion of the valve stem 49 from Vmoving to the right, thus tending to cause the bottom of the valve stem carrying the lapper valve 43 to move to the left. At rst the valve stem 43 lwill bend slightly about fulcrum 50 but ultimately the force of the magnet 48 will be overcome and the apper valve will snap open and come to rest against adjustable stop The action of the magnet 48 is to produce a snap action opening and closing of the exhaust port 42 and to produce a difference between the pressures in the Bourdon tube required for opening and closing the exhaust port. The adjustments for the magnet 48 and stop 5| permit the difference between the opening and closing pressures to be adjusted. 'Ihe entire assembly is pivotally mounted at 53 and is adjusted in position by .means of link 54 so that the range of operating pressures set by adjustment of the magnet 48 and stopj 5| may be made to correspond to the range of, travel of the end of the Bourdon tube produced by pressure which is conducted thereto through conduit 41.

Whenever exhaust port 42 is` closed gas under pressure is supplied through conduit 34 to the space above diaphragm 32 ofthe motor valve 30 and moves the valve to closed position. This is the normal or rest position of the equipment corresponding to intervals between lifting operations. Whenever the pressure in the well casing annulus drops the Bourdon tube moves to open the exhaust port 42 thereby allowing gas passing through orice 4| to exhaust to atmosphere. Because of the drop in pressure thus created across orice 4| the pressure in conduit 34 is insufficient to hold motor valve 30 in closed position and the spring 33 opens the motor valve.

A by-pass line 60 controlled by a pressure regulator 6| permits small quantities of gas to ow into the casing annulus as long as the pressure in the casing annulus is below the closing pressure to which adjustable regulator 6| is set. The rate of flow through by-pass line 60 is regulated by means of needle valve 62. If desired the bypass line could be omitted and the same effect could be obtained by providing means to open the main motor valve 30 a slight amount whenever the pressure in the annulus is below the nor- .mal pressure. For the purpose of controlling the :gas flow in the surface valve mechanism when rst installed or when being repaired a number of manually operated gas valves 63, 64, 65 and $6 are provided. r

The subsurface valve mechanism comprises a main bellows actuated valve 10 and a pilot valve 1| and'also preferably a check valve 12. The pilot valve is constituted by the lowermost unloading valve and is identical with the other unloading valves 2| thereabove. VThe check valve comprises a ball seat 13, a ball valve '|4 and a ball retaining cage '15.

The main gas valve 10 may be identical with the pressure operated unloading valvel previously described. As shown in detail in Figure 2, it comprises a valve member 16 closing against valve seat The valve member 16 is carried the casing annulus. The housing 80 is supported by a pipe 82 which is suitably connected to the tubing as shown at 83. l

When the apparatus previously described is rst installed in the well and before the packer is set, the head of oil in the tubing and casing annulus is initially lowered by means of the unloading valves. All the float valves 2l and 1| below the level of the oil will be open so that when gas is admitted to the annulus the gas pressure will force oil from the annulus tothe tubing through the uppermost of the open unloading valves and out through the tubing. As the oil rises in the tubing past the unloading valve immediately above, that valve will open admitting gas to the oil and aerate it. This will continue until the level of the oil in the casing is lowered below the inlet to the next unloading Valve, whereupon gas will be `admitted through that valve to aerate the oil in the tubing thereabove which will cause the gas valve above to close because of the lowered specific gravity of the oil. This process will continue, foil entering through one unloading valve and gas entering throughthe unloading valve immediately above until the oil level is lowered beneath the lowermost float valve 1|. The gas pressure will then be increased Y slightly so as to rst open the bellows valve 10 by a valve stem 18 that is connected to a sealed.

to force oil therethrough into the tubing, and then when the level of oil is below bellows valve 10, to admit gas to the tubing through the valve 10 while forcing the oil into the tubing through the perforated section at the lowermost end thereof. When the oil has been lowered well below the level of the packer, the packer is set and the system is then ready for normal operation, the gas pressure being returned to normal operating pressure so that the valve 10 is closed.

Oil will begin to rise in the tubing past the check valve 12 into'the accumulation chamber 20. The packer will prevent the oil from rising in the annulus. When the oil hasl finally lled the accumulation chamber it will rise in the tubing section immediately above and when it has risen to the top of the fluid column of the liquid float valve 1| the float valve will open admitting gas from the annulus to the tubing. Since there is no oil above the valve 1| this gas will merely exhaust out the top of the tubing and will immediately cause a drop in pressure in the annulus. A drop in pressure in the annulus will cause the Bourdon tube 45 of the surface valve mechanism to contract thereby opening the apper valve 43 and reducing the gas pressure in the chamber above the diaphragm 32 of the motor valve 3B. The motor valve will open admitting gas to the annulus at a much higher rate than it is being exhausted through the pilot valve 1| so that the gas pressure in the annulus will increase. A slight rise in the annulus gas pressure above the original starting pressure will open the bellows valve 10 and admit gas to the tubing below the accumulation chamber. The check valve 'l2 will close, preventing the gas pressure from acting on the formation and the gas will lift the oil in the accumulation chamber through the tubing The rate at which gas is admitted to the annulus through the motor valve 30 at the surface is higher than the rate atv which it is exhausted through both the pilot valve and the main subsurface gas valve so that the annulus gas pressure continues to rise. When the gas admitted to the tubing thrcugh'valve` Ill has lifted the oil past the pilot valve thepilot valve closes, since it is responsiveV only to the density of Athe fluid opposite the valve, which is then gas. 'Ihis causes the annulus gas pressure to increase at a slightly higher rate. When the annulus gas pressure reaches a predetermined value the Bourdon tube 45 will be expanded sufficiently to allow the magnet 48 to close the apper valve 43 of the surface controls. This Will cause the motor valve 30 to be closed. Gas will continue to enter the tubing through the subsurface gas valve until the annulus pressure drops to the starting pressure, at which point valve 10 closes. The gas then in the tubing will continue to expand and carry the oil to the surface.

The time of closing of the motor valve 30 at the surface is adjustable at the surface and. can be adjusted by trial until it closes when just sufficient gas has been admitted to the annulus to expel the oil from the tubing. Since the volume of the annulus above the packer is fixed, the amount of gas admitted thereto necessary to raise the pressure a predetermined amount corresponds to a denite quantity of gas. Also, since the volume of the tubing between the level of the subsurface gas valve 10 and the pilot valve 1| is fixed, a definite quantity of oil is accumulated in each cycle of the intermitter. Therefore, the gas-oil ratio in an intermitter operating on a system according to the invention is not only adjustable from the surface but is fixed for any given adjustment.

In case there are any leaks in the casing it is desirable that a small quantity of gas be fed to the annulus to maintain the gas pressure at the normal between-lifts level, for if the pressure should drop sufficiently to actuate the surface controls a false operation would occur. The by-pass line 60 containing the pressure regulator 6| and needle valve 62 serves the purpose of maintaining the annulus gas pressure between lifts. The needle valve 62 is adjusted so that the rate of admission of gas to the annulus through the by-pass 60 is much lower than the rate of exhaust from the annulus to the tubing when the pilot valve 1| opens so that Ythe by-pass does not prevent actuation of the system at the proper time.

The graph in Figure 3 plots the variations in annulus gas pressure during each cycle of operation. At a the system is at rest and the pressure is normal. At b the float valve 1I opens causing the gas pressure to drop until at c the surface gas valve opens. The pressure then rises until at d the main subsurface gas valve opens. I'he pressure continues to rise at a lower rate until the pilot valve 1| closes at e. The pressure then rises at a slightly higher rate until the surface gas valve closes at f. The pressure then drops until the subsurface valve 10 closes at g at which point tle pressure in the annulus is the same as that a a.

The system shown in Figure 4 is generally similar to that shown in Figure 1 and to the extent the systems are identical like reference characters have been used to designate like parts. The main differences between the systems of Figure 1 and Figure 4 are, rst, the surface valve mechanism of the Figure 4 system includes a kinetic type of mechanism for initially opening the main gas valve instead of a static pressure type of mechanism as shown in Figure 1, and second, the pilot valve shown in Figure 4 is modified so that gas is admitted behind the oil rather than exhausted to the tubing. In addition, pressure type unloading valves are shown in Figure 4 1n place of the float type unloading valves of lFigure 1 anclthebottom hole construction is slightly modified in Figure 4.

The surface valve mechanism comprises motor valve 90 similar to the motor valve 30 of Figure l except that downward motion of the valve stem opens the valve instead of closing it. Gas for actuating the motor valve is taken from the main gas line through conduit 36 and a combination filter, drip and pressure regulator shown at 9| to one end ofa hollow body 92 which is connected to conduit 34 leading to the motor valve. Body 92 contains a restricted passage 93 between the conduits 36 and 34, and the end of the body opposite to that at which conduit 36 is connected is provided with two openings 94 and 95 to the atmosphere. Opening 94 is normally closed by a valve 96 carried on valve stem 91 connected to one end of a Bourdon tube 98. Stem 91 has an arm 99 extending at right angles therefrom which engages a trip lock later to be described. The other end of the Bourdon tube is fixed at 46 and connected through conduit 41 to the main gas supply line I6 on the down stream side of' the motor valvev 90. The other opening 95 in the hollow body 92 is normally open and is adapted to be closed by valve 00 carried by a valve stem 10| connected to a diaphragm |02. A spring |03 normally urges the diaphragm to the left to maintain the valve |00 in open position. The chamber to the left of the diaphragm is connected by conduit |04 to a dart valve |05 and thence through conduit |06 to the gas supply line I6 on the down stream side of the motor valve 90. The chamber to the left of the diaphragm |02 is also provided with an exhaust port Referring to Figure 5 there are shown the details of the dart valve |05 which comprises a valve member |08 carried by a valve stem |09 which is connected at its opposite end to a check valve H0. A helical spring connected to the check valve l|| 0 and also to valvestem bearing ||2 is normally in tension tending to close the valve |08. Bearing l2 is carried inside a conduit ||3 which forms a T connection with the conduits |04 and |06 and which is connected to the gas supply line I6 down stream from the conduit |06. Whenever there is a substantial ow of gas through gas supply line I6 a portion of the gas will also iiow through conduits |06 and ||3 thus closing check valve I|0 against its seat 4. In this connection it is to be noted that the bearing ||2 is provided with apertures ||2a sucient to permit a substantial flow of gas and the check valve ||0 has sufficient area so that the dynamic pressure of the flowing gas will be sufficient to overcome the slight tension of spring Ill. When the check valve ||0 closes the valve |08 opens admitting gas throughconduits |06 and |04 to the chember to the left of the diaphragm |02, thus actuating valve |00 to close port 95 in the hollow body 92. This will cause the pressure in hollow body 92 on the left side of the orifice 93 to build up and this pressure will be transmitted through conduit 94 to the motor valve 90 which will be opened. When stem |0| moves to the right to close valve |00 it also carries arm 84 connected thereto to the right. This causes the end of trip lock lever 86 to move over the top of arm 99 on valve stem 91. Upon an increase in pressure in the gas supply line I6 on the down stream side of valve 90 gas conducted through conduit 41 to Bourdon tube 98 will expand the tube and lift valve 96 to open port 94 to the atmosphere. This will cause the bIrltgl Valve to close. As the Bourdon tube gaseosa expands it also carries arm 99 on stem. 91V upwardly past end 85 of the trip lock lever 99 which turns about pivot 8lA on the right angle extension 88 of arm 84. A subsequent decrease in pressure in the gas supply line I9 on the downstream side of valve 99 will tend to cause Bourdon tube 98 to contract and tend to move valve stem 91 downward. Its movement is blocked however by end 85 of trip lock lever 89 which. is under arm 99 on valve stem 91. Lever 86 is prevented from turning clockwise by pin 89 on its opposite end from end 85Vpin 89 abutting against the under side of extension 89 of arm 84. Valve 98 thus' cannot close until valve 99 opens again carrying the trip lock lever out of the path of arm 99.

*The bottom hole construction shown in Figure 4 differs from that of Figure 1 in that the casing is cemented above the level of the formation rather than below and a liner I I5 having aperforated screen portion ||6 on the lower end thereof isv supported within the formation and sealed at its' top to the casing as shown atl IIl. The bottom end. ofthe screen is closed as indicated at |`|9`. A check` valve 12 is providedY at the bottom end of the tubing as in the system, shown in Figure 1 and an accumulation'chamber 20 isl provided thereabove. However, the packer I9 is above the accumulation chamber rather than below as in the previously described form of the system. This is. made possible by' the provision within the accumulation chamber of a macaroni string I I9 which extends from a point slightly above the. check valve 'I2 to a point a slight distance above the top of the accumulation chamber where it isr connectedto and sealed with the interior of the tubing as shown at |20. With this arrangement the main sub-surface gas valve l0 can be connected to the top of the accumulation chamber and when it opens the gas will force oil downwardly in the accumulation chamber and thence upwardly out through the macaroni string.

The pilot valve |2| differs from the valve 'H of Figure 1 in that the gas conduit |22 extends downwardly'` from the valve rather that upwardly. The purpose` of this change is to admit the gas to that, portion of the tubing below the seal so that the gas will aid in lifting the oil; instead of wasting. Conduit |23 places one side of the diaphragm for actuating the valve. in communication with the liquid in the tubing and the liquid float column extends upwardly from the other side of the diaphragm the same as in' the valves shown in Figure 1. Although. not shown inthe. schematic diagram of the drawings there is av separation chamber at the top of the liquid column 21|V to prevent the liquid Ifrom. mixing with the fluid inthe tubing. This is fully described in the Thomas patents previously referred to.

The unloading valvesl |25 are of a construction similar to thatv of the main subsurface gas valve T0 butl are set to open at higher pressures than, any pressure existing in the annulusA during thev normal operation of the system. The opening pressures of these valves are set in descending order of pressures-.accoding to the distanceV below the surface, the top valveopening at the highest pressure. When the apparatus is first installed the gasV pressure in the annulus is initially raised to a pressure sufficient to open the uppermostv of the unloading valves |25 and' then after theA oil level' lowers the gas pressure is gradually reduced, thus allowing the upper valves I4 to close successively while linaintaining at least one valve open to admit gas to the tubing and lower valves open to admit oil. Aswith the system shown in Figure 1, when the oil level has been lowered well below the level of packer I9 the packer is set, thereby preventing any oil from rising into the annulus above.

In the operation of the system in Figure 4 oil rises past check valve 12 into the accumulation chamber 20 and the macaroni string H9. Any

gas already in the accumulation chamber, either lift gas from the casing annulus or formation gas, escapes into the tubing through port |21 in the macaroni string so that the system is never rendered inoperative by gas lock. When oil has filled the accumulation chamber and risen above the seal' |20 to a level near the top of the liquidv fluid column |24 of pilot valve |2| the pilot valve will open to admit gas to the accumulation chamber through conduit |212. This will cause a flow of' gas through the surface gasv supply line I6 even though motor valve 90 is closed since there is considerable volume of gas in the line I6 on the downstream side of motor valve 90. This flow of gas in line |20 will actuate the dart valve |05 admitting gas to the left side of diaphragm |02 closing valve |00 and thus admitting gas through conduit 34' to actuate motor valve 9o which moves to the open position. Gas will then be admitted'to the annulus at a higher rate than it is being admitted to the tubing through pilot` valve |"2I and hence the annulus gas pressure will rise rapidly. When the pressure reaches aV predetermined point higher than, the initial annulus pressure the main subsurface gas valve will' open admitting gas to the space above the oil in the accumulation chamber 20. This gas together with that ad.- mitted by pilot valve |2| will eject the oil from the accumulation chamber through macaroni string into. the tubing.

As with the embodiment shown in Figure l the rate of admission of gas through surface valve 9 0 is greater than the rate at which it is admitted to the accumulation chamber through pilot valve |2| and main subsurface gas valve 10 so that the annulus gas pressure will continue to. rise. the accumulation chamber and lifted beyond the pilot valve |2| the pilot valve will close. The annulus gasl pressure, will then rise at a slightly higher rate. When the annulus gas pressure reaches a` predetermined value the Bourdon tube 98 of the surfacevalve mechanism will expand opening port 94 in hollow body 92 thereby reducing the pressure ltransmitted to the motor valvethrough conduit34 and. allow the spring 33 to. closev the valve. The, annulusy gas pressure willA then drop. The Bourdon tube 90 will contract tending to re-close port 94 but will be prevented from so doing; by the. trip lock lever 86. The pressure `drops toy the starting pressure, at whichpoint subsurface gas valve 10 closes. This stops theiiowv of gas in line lliA and the dart valve closes causing valve |00 to` open. which in turnr When the oil` has been expelled from.

pressure at which motr'valve 90 is closed by expansion of Bourdon tube S8 can be adjusted at the surface. In the system of Figure 4 this adjustment can be made by changing the length of the valve stem 91 which can be provided with an adjustment such as that shown at |26. Thus the quantity of gas admitted to the annulus, and hence to the tubing, is adjustable at the surface so that the gas-oil ratio can be set at the desired value. No by-pass gas line around motor valve 90 is required in the system shown in Figure 4 since the system is not operated by a simple drop in the static pressure in the annulus such as might be caused by leaks in the casing but requires a substantial flow of gas in the gas supply line i6 in order to operate the dart valve |05. The dart valve |05'has the further advantage that it can be made to respond more quickly to the opening of the subsurface pilot valve so that the initial action of the system is quicker than thatof the system lshown in Figure 1.

Referring to Figure 6 there is shown a graph of the variations in gas pressure in the annulus plotted against time. The cycle is substantially the same as that for the system of Figure 1. It may be noted, however, that the initial drop in pressure prior to opening of the main surface gas valve indicated at c is less than the corresponding drop in pressure shown in Figure 3. Also the rate of drop initially from b to c is less in Figure 6 than in Figure 3 because the gas from the pilot valve is admitted behind the oil in the Figure 4 system instead of ,allowed to exhaust into the tubing about the oil as in the system of Figure l. For the same reason the slope c-d is somewhat steeper in Figure 6 than in Figure 3. Also, since the gas admitted to the accumulation chamber by the pilot valve |2| helps to raise the oil from the accumulation chamber the oil will rise beyond the accumulation chamber more quickly in the Figure 4 system than in the system of Figure 3 so that the time d-e is somewhat shorter.` The remainder of the Figure 6 cycle is substantially identical with that of Figure 3.

Referring to Figure `'1 therev is shown a modified form of subsurface valve mechanism in which the pilot valve |2| is eliminated and in which the buoyancy member for initially actuating the mechanism is a solid heavier than oil instead of a liquid float. The subsurface gas valve designated generally by reference number |30 is located within the tubing string in a section |3| of somewhat increased diameter which connects the upper portion of the tubing string to the accumulation chamber 20. The valve |30 is contained within a housing |32 which is supported within a receiver |33 mounted inside the tubing section |3| and connected thereto by supporting struts |34 and |35. The tubing section |3| is of such diameter that the annular space between the receiver |33 and tubing section |3| is equal to the area of tubing so that there is adequate room for upward passage of oil around the valve |30. A plurality of ring shaped seals |35, |31 and 38 made of some resilient material such as neoprene are secured to the inner wall of the receiver |33 and are of slightly smaller internal diameter than the outside diameter of the 'valve housing |32. When the valve is lowered through the tubing supported by means of knob |39 connected to the end of a wire line the tapered bottom portion |40 of the valve housing will guide the valve centrally within theA receiver |33 and when the Amain part of the valve vhousing |32 enters the'receiver |33 it will compress the sealing rings |36, |31 and |38 to make a tight joint therewith. The bottom |40 of the Valve housing will rest against the bottom of the receiver |33. The wire line can then be manipulated to free it from the knob |39 leaving the valve in place. Whenever it is desired to remove the valve it can be shed out by means of a wire line.

The valve housing |32 is divided into three chambers by means of partitions |41 and |42. There are ports |43 and |44 in the side of the Valve housing, port |43 being above partition |4| and port |44 being between the partitions. Seals |31 and |38 between the valve housing and the receiver located respectively above and below port |44 and both below port |43 form an annular space in communication through port |44 with the central chamber of the valve housing between partitions |4| and |42. A conduit |45 connects this annular space with the annulus between the casing and tubing. The space below partition |42 in the valve housing |32 is connected by port |46 to the space below the seal |36 in the receiver |33. This latter space in the bottom of the receiver |33 is connected through portA |41, check valve |48 and conduit |49 to port |56 in the top of the accumulation chamber 20.

Port |5| provides a passage for communication between the central and lower chambers of the valve housing |32 and is provided with a valve seat |52 which is normally closed by valve |53 carried on the end of valve stem |54. The upper end of valve stem |54 is connected to the bottom end of a bellows |55. The upper end of bellows |55 is secured to partition |4| with the open end of the bellows surrounding port |56 in the center of partition |4| with its open end surrounding the port |56 and sealed to the partition |4| the same as bellows |55. The upper end of bellows |51 is closed and a sealed chamber thus provided within the two bellows |55 and |51. The two bellows will hereafter be referred to together as a double bellows.

Circular plate |60 is secured to the top of the upper bellows |51 and is adapted to bear against stop |6| which is in the form of a cylindrical open mesh cage surrounding bellows |51. Engagement of plate |60 with stop |6| limits the Y downward travel of plate |60 and thus limits the degree to which upper bellows |51 can be compressed. A cylindrical weight bar |62 rests on top of plate |6|. This bar may be quite long and is guided in its up and down travel by means of ribs l|63 and |64 (see Figure 8) traveling between guides |65 and |66 on the top of valve housing |32. The rit between ribs |63 and |64 and guides |65 and |66 is suinciently loose so that oil entering through ports |61 and |68 in the receiver and between the seals |36 and |31 can pass inside the valve housing to the space above partition |4| around upper bellows 51. Additional communication is provided by port |43 in the side of the valve housing |32. The space within the double bellows |55 and |51 may be filled with gas under pressure which normally is slightly higher than the pressure within the casing-tubing annulus so that valve |53 rests against seat |52 and closes port |5I. The weight |62 is only slightly heavier than is necessary to cause upper bellows |51 to be compressed so that plate |60 rests against stop |6|. `The operation of the subsurface valve Amechanism of Figure 7 is similar to that of subsurface The eas pressure will co. surfaceeeontrolsfzar aetuatedfztof-.closertberxnain esuriaee .esas :valve- `vvalve mechanismof Figure ...4. Oil willrise. in

the` tubingifpast checkvalve12 into the accumulation chamber. Check valve |48 prevents ,the oil from `entering thegas valve housing. (A similar oil check valve could be H.used with .the

g subsurfacelgas valves yshown in liiguresd and 4.)

sWhen the oil has filled fup the .f accumulation `chamber .U20 and risen in thel tubingy section lI6 I to .-expand .It isi neceSSaly that the areayof the `bottom Aof the weight |62. be considerablylarger that the reduction in force against., the top of the` bellows due .tothe buoyancy effect ,on ,Weight |62 will. be.. greater thantheincreaSed forceon the. bellows duetothe downward.weightofthe oilabove it. `The .area .of'thebottom of-the weight, the area of the top .of the bellows, .the density of the weightand the length of 4the `.weight ShC'uld be so chosen as to produce the ,desired initial downwardforce upon the. bellows .and the desiredv reduced force upon thej ,b e l1ows lwhen .oil has risen tolthetop of .the weighty .The density. of the T-weiaht can .beadiusted `r`for .anygiven length thereof. by .drillinaholes .the side thereof 4which .ca nhe 'filled .with lead, ..915 if it is desired z .tol .lighten .the weight, canbe. left empty. .InW a .usualsystem V.nsinagas `pressure of -around "500 pounds. per square 'inch .the weight |162. mevbeas heavyes. 4.0001500, pounds- This heavy weight serves :the additional l.purpose of retaining the valve ,housing 3 |32 Seated Within .the receiver |33.

When the bellows |51 expands upon the buoyingup of weight |.62, the internalpressure of the l'double bellows |55 ,and |51 will be reduced below the normalpressure .within-thecasing annulus.

' This will cause the lower* bellowsi |55" to` becom- "pressed,',t-hereby opening the main gas valve |53. I'Gras will iiowY through ports' |5I and;` |46 into-the bottom of thereceiver |33 a ndrthenee through conductor |49 ato-the -top Aof-the -accumula-tion chamber 20. The gas willvforce thevoilydownf ward "in the accumulation -c-hamber fand -up through the macaroni-string I ISWandthenee'lout through tubingsect-ion- I3 hand tubingstringvv I I.

AThe drop Anjpressure `in thefcasing annulus; thus caused will -1 actua-te L'the i surface ivalve Wmejcha- 1 nism before the casingfpressureedropsf suiciently to close valve |53-byexpansion of -ilower bellows ia-andalso-before the gas admitted'to'laocumu- 1 lation chamberf2-has-had-suflicient time-toraise f the oil -pastthe A`buoyancy member i 62 1- which Iwould cause the upper bellows :to contract thereby expanding Lthe l .lower-f4 bellows.: again' and l closing ther-valve |53. A`As .f soon.as the :surface 4controlsare-actuated the main-:surfacegas-valve ropensE andthe :,annuluspressurexbegins to Vbuild "up` again. -The pressure, will build up" fast enough sofv that the :pressure :.wi'll .'be above vi-.theenormal pressure of theannulusia sufllcientizamountfto 1 .weight 62 "tof-.compress :fbellows .|51 until plate I 60. restsonrstopi I6 1Any5 iurthencompression oi-.bellows .|51;.such;:as mig-ht otherwiserocur :because .ofythegincrease impressum.intheitubine :due vto :the ..gasvwill rbe :rrrevented :fbyrstep 516| .inne to ;rise;.unti1f. the

l.'-lfhe rannulus pressure will receiver.

-18 .then fall untilitreachesthe original pressure, atwhich point bellows. |55 will expand and close valVe.I53. It is to benoted that thedirection ofgas@ flow through 4port |5| is such as tojhelp .valve |53 .close, thereby preventing anyundue amountof metering action on` closing of the valve. Uponclosure of the valve the pressure beneath rthe valve will decrease, thereby increas- Vin gthe differential, tending. to maintain the valve closed. .The gas in the tubing willcontinueto ex- .pand and expel the oilv at. the surface of ythe well.

at |1| and is positively secured to the plate |60 ontop .of the bellows |51. `In order to .supply .thenecessary force to maintain bellows |51 suincientlycompressed toelose valve |53 a spring |12 isV provided `between the top |13 of the valve housing |32. and the top |14 of the oat |10.

Since the `float |10 will not be. as heavy. as

. the weight |62 it is desirable to provide some means for retaining the valve housing within .the For this purpose .an annular groove |15 is formed in the outside of the valve housing .|32 near the bottom 1end thereof. .Referring `to Figure 10, one or more spring -presseddetents I16may be provided around the inner wall of the receiver |33. As shown the detent |16 is spherical to t .within the arcuate section of the-groove |15. The detent |16 is `c arriedwithin lthe housing |11 whichis provided with threads |18 for engagement with corresponding threads in aperture |16 formed in` receiver |33. The ldetent |16 has end for engagement with stops |82v which limit the outward travel of thedetent under influence of compression spring |83. The shoulder I8|! on .housing |11 is of slightly less .thickness than seals |36, |31 and I38in the receiver |33.

When valvehousingv |32` is inserted in the re- .ceiver I33 it will-.first compressthe detent |16 withinthe housing |11 until thegroove |15 is The curved surtenttobe forced back, into its housing when sufficient pull is lexerted .on nob.|33. However, the

A.slopeof Vthe, abutting. surfaces of detent |16` and groove |15 is sufficiently high sothat considerable force must beexerted before thevalve can .be removed. If desired the valve housing retaining -meansshOWnin Figure 10 canbe usedwith the constructionshown in Figure 7 and also .with any of the other removable valve constructions shown in iigures yet tobe described.

The `operation of the subsurface valve mechanismshown in Figure v9 isexactly the ,same .as

the operation of the subsurface valve mechanism Starting., at a -the pressure is ,the normal, or rest Vpressure. ofthe system; b, representsthe initial opening of the Lsubsurface gasivalve; bc indicates the initialdrop in pressure ,prior toactuation of the surface valve mechanism; c is the #point at l whichv the main surface gas valve opens; C-.f indicates ,thexrise inrressure ntheannulus .1 following opening `of ,the .--.surface sas A valve; f ...is the peint :at i. which. the f surieee eas valve L is l against plate |80 on upper bellows |51.

i9 closed following a rise in pressure to the predetermined point; f-g shows the drop in pressure following closure of the main surface gas Valve; g indicates the closure of the subsurface i gas valve upon return of the annulus pressure to the starting pressure. It will bernoted that the pressure diagram shown in Figure 11 is quite similar to thoseshown in Figures 3 and 6, the principal differences lying in the elimination of the slight kink d-e of the rising gas pressure line c-J due to the elimination of the pilot valve.

In Figure 1.2 there is shown another modification of the system of the invention operating on the first described cycle. A single valve subsurface valve mechanism |85 is used similar to those of Figures '1 and 9 and to be distinguished from the two valve subsurface valve mechanisms of Figures 1 and 4. The bottom hole completion is the same as that shown in Figure 4 comprising a liner ||5 and a screen I8. Also as in Figure 4 an accumulation chamber 29 having a macaroni string ||9 is used and pressure type unloading valves are provided. The surface valve mechanism is similar to that shown in Figure l except that a clock mechanism is used to determine the time of cut off of the main surface gas valve.

The subsurface valve mechanism |85 is shown in detail in Figure 13. Since the mechanism is so similar to that of Figure 7 only the differences will be referred to. In place of a buoyancy member a differential bellows |88 is provided secured to the inside of tapered top |88a of the valve housing |32. The bellows |88'is under internal pressure of gas or some other elastic means such as a spring which causes button |81 carried by plate |88 secured to bellows |88 normally to bear Plate |88 also cooperates with open mesh cage type stops |89 to limit compression of bellows |88.

The force of button |81 helps spring |12a to normally hold the bellows |51 compressed with plate |89 bearing against stops |8|. The area of the end of bellows |88 i-s greater than that of bellows |51 so that when there is an increase of pressure in the tubing the increased force upwardly compressing bellows |86 is greater than the increased downward force on bellows |51. The increased upward force on bellows |98 "reduces the downward force transmitted to bellows |51 by button |81. The net effect therefore of the initial increase in tubing pressure is to reduce the force on the end of bellows |51. The relative areas of the bellows and their internalV pressures and the tension of spring |12a are so chosen'that when a predetermined head lof oil builds up above subsurface valve mechanism |85 the upper bellows |51 will expand thereby reducing the internal pressure of double bellows IE5-|51 and causing lower bellows |55 to contract, opening valve member |53. If desired, stops |9911 similar to stops |89 can be provided to cooperate with plate |88a on the lower end of bellows |55 to limit its further compression.

When the gas reaches the tubing the increased pressure acting on the differential bellows |88 compresses it until `plate |88 rests against stops |89 while at the same time the increase in tubing pressure on upper bellows |51 is sufficient to more than make up for the drop in force transmitted through button |81 so that the upper bellows |51 contracts again until plate |89 rest-s against stops |8I. The upper bellows is then independent of the differential bellows, the button |81 being out of contact with plate |89. lf'he action of differential bellows |88 is thus the 20 same as that of the buoyancy members of Figures 7 and 9 in that the build up of oil causes the upper bellows to expand but later the presence of gas in the tubing causes the upper bellows to contract again.

The surface valve mechanism comprises a motor valve 30 which is moved to closed position upon increase in gas pressure above the diaphragm 32. Gas pressure for actuating the motor valve is supplied from conduit 38 connected to the main gas supply line I8 through a combination lter, drip and pressure regulator 9|. A hollow body I8 connects the conduit 38 to the conduit 34 which opens to the space above diaphragm 32. A restricted passage 4| limits the rate of gas ow through body I0. A apper valve |90 is disposed to normally close port 42 in hollow body |D, being pivoted at |9| and urged to port closing position by a spring |92. The apper valve |99 is periodically opened and closed depending on the position of cam |93 which is rotatably mounted on shaft |94 driven by stop clock motor |95. Motor |95 is controlled by push lever |98. The construction is such that upon upward motion of lever |98 motor |95 operates to turn shaft |94 one revolution and then stops. The motor will operate to drive the shaft |94 one complete revolution even though lever |98 is moved downwardly prior to completion of one revolution but will not operate more than one revolution even though lever |98 is maintained in its upper position. To cause the clock to start again the lever |98 must be rst moved down again and then back up to the motor starting position. lStop clock mechanisms of this type are known and need not be described in detail. Lever |98 is actuated by Bourdon tube |91 connected through conduit 41 to main gas supply line I8 on the down stream side of motor valve 30.

The surface valve mechanism also includes a by-pass line 80 having a pressure regulator and needle valve 82 therein the same as in the system K shown in Figure 1.

In operation of the system of Figure 12 when sufficient oil has built up past check valve 12 into the accumulation chamber 20 to fill the accumulation chamber and then has risen in the tubing to the predetermined height the upper bellows |51 will expand, the lower bellows |55 will contract, and thevalve member |53 Will open admitting gas through ports |48 and conduit |49 to the top of the accumulation chamber 20. This will cause ardrop in pressure in the annulus which will permit the Bourdon tube |91 of the surface valve mechanism to contract thereby pushing up on lever |98 and starting clock motor |95. 'Ihis will turn cam |93 from the rest position shown in Figure 12 to a position where the high part of the cam will press against the upper end of the stem of valve pivoting it about point |9| and opening port 42. 'Ihis will reduce the pressure transmitted through conduit 34 to the upper surface of diaphragm 32 and allow spring 33 to open motor valve 30. The drop in pressure in the casing annulus required to actuate the surface valve mechanism is not suiiicient to close valve |53 by expansion of lower bellows |55, the internal pressure of the double bellows |55|51 being reduced due to expansion of the upper bellows |51. Furthermore, the surface valve mechanism will be actuated before the gas admitted to accumulation chamber 2|) has had su'icent time to raise the oil past the upper bellows |51 which would cause the upper bellows to contract under the gas pressure, thereby ex- Ypressurereturns tothe desired pressure. cycle vwould-then be complete. -preferable to-set the surface controls'at .a vpres-- regresaba@ vpandingfthe lower-bellows-fagain and closing the :valve |53 prematurely.

mWhen .themotor-valve opens gas willbe Vad- 'After a predetermined time clock motor |95 will have driven cam |93 to a position where it I"permitsfspring |92 to close valve |90 thus pre` venting exhaust yof air from hollow body through port 42. This will increase the pressure transmitted through conduit 3G to the upper surface of diaphragm 32 and close motor valve v3|).

"Thelannulus gaspressure will then start to fall.

When the annulusv gasvpressure falls to a point VonIysliglitIyabove the starting pressure the lower y 7v`bellows |55 iwillfexpand, the double bellows pressure being high again `due to compression of the upper'bellows, thusclosingthe subsurface gas valve. The gasin the tubing will ycontinue to expand andraise the oil to the surface. As the tubing-"pressure drops the upper bellows |51 will momentarily expand again opening the subsurface valve 4but'the pressure will quickly drop lfurther and differential belows |86 Vwill expand 1 and compressbellows |51, again closing the subsurface valve. The cycle is complete.

VV"The normal Vpressure in the annulus is mainrtainedJdespitel any leaks in the casing by the bypass'lil of the'surfacevalve mechanism. 'If def sired" the regulator 6| could be set to maintain the annulus pressure at that pressure at which fthe--subsurface valve first closed. In such case -when`the annulus pressure drops due to the Ymomentary reopening of the subsurface valve at the end of the cycle gas would enter the Aannulus n'through-theneedle valve 63, regulator 6| `and Vbypass 6|l at a 'slow rate until the annulus The However it is sure corresponding yto that at'which the sub- -surfacevalvel-re-closes to` avoid any'possiblity of f false `actuation of thesurf aceA valve mechanism Vby-'t'heslight drop'in annulus pressure at the fend of the'cycle.

Referring to `Figure 14 which shows a graph -ofrthefpressuretimejrelations in the casing an- A"nulusduring-a cycle, thenormal annulus 'pressure is indicated at a. Atlpoint b the subsurface valve -opens and the gas pressure drops until the point c is reached at which surface gas valve lIhe annulus gas pressure then rises -until at point f the surface gas valve 30 closes.

The gas pressure then fallsv to point w at which -the-subsurfacegas valve closes. Atpoint ythe -sub'surface'gas Vvalve vopens again momentarily *but A.re-closes atp-point y.

-solely upon the elapse of a predetermined timel governed by theoperation of'the 'clock motor,

whereas inY theprevious systems'the cut-off was -determinedbythebuild up ofpressure inthe ansnulus. VAI-Ioweverfthe'system of (Figure V12-will lf-functionlv to admit A a 4predeterminedr quantity "of valve housingY 2E) l.

i gas to the annulus the sameas the othersystems because the flowthrough the orifice formed by motor valve 30 will vbe fairly uniform for any given supplypressure and annulus pressure so that the ow through the motor valve 30 for a definite timecorresponds tok the .admissionof a definite quantity of gas. Thetime at which valve 30 opens is adjustable by varying the length of lever ISSor the` relative positions of the clock and Bourdon tube. The time at which the valve 30 closes is adjustable by varying the speed of the clock motor or by changing the cam |93to substitute a cam of a different shape. If desired additional control means may be provided to maintain constant the rate of flow from'the source of lsupplyto the annulus regardless of changes in the supply pressure and the annulus pressure. Such means could be further compensated to `care for changes in the density ofthe gas and'changes in the ambient temperature. However such highly accurate control of the rate of flow is usually unnecessary.

Referring to Figure 15 there is shown a gas lift system operating upon the second described cycle. Many of the parts of the system are identical or substantially the same as the partsA used in the other forms of the invention previously described and the like parts have again been given like reference numbers.

The .surface valve mechanism of this system differs'from that of the system of Figure 12 in that a dart Valve controllinga diaphragm motoi1` is used to initially start the clock motor in place of the Bourdon tube. The dart valve is of the sameconstruction as that shown in-Flgures 4 and 5.

Spaced at intervals along the wellftubing `are unloading valves 2| -of the liquid lioat typethe same asshown in Figure 1. The lowermost un` loading valve 2|, however, does not serve as a pilot valve as in Figure 1. Beneath the accumulation chamber 2|) in `a position similar to that occupied byfmain gas valve 10 of vFigure l there is a main gas valve 200.

Referring to Figure 16 there is shown the internal construction of valve 200 which isV containedA within a housing 20|. YThe housing 20| is divided into two compartments'by `a partition 2632. A passage 203 through thepartition 202 may be provided with ya liquid checkvalve 2036i sim'iiar to valve |48 of-Figure 7. The passage is normally closed by `valve-rrnember 204 resting against valve seat 205e. Valve member 204 is carried cri-valve stem 205 connected to the top end of sealed bellows 206. The bottom end of bellows 206 is'connected to the bottom of If desired the top of bellows 226 is provided with a plate 201 forc'ooperating with cage type guards 208 to limtfcompression of bellows 206 thereby preventing thevbellows from' being injured in case excessive pressures are presentwithin the valve-housing 20|. The

arrangement is'similar to that of `liigure v13 jbellows moves against the-stops and comes-to rest. "-In' addition, the open valve -position is fixed so that the rate of gas ow is unaffected by changes in valve position once the valve has opened until it closes again.

Valve 204 is normally locked in closed position by means of hook 209 carried on stem 2|0 engaging beneath arm 2|| on the side of valve stem 205. The stem' 2I0 is yconnected at its opposite end to the top of bellows 2I|. The exterior of bellows 2|| is exposed to the pressure in the upper chamber of valve housing 20|, the upper chamber being connected by conduit 2|2 to the interior of the tubing Il. The interior of bellows 2|| is exposed to the pressure in the lower part of valve housing 20| through port 2|3 in the partition 202. The bellows 2 |I completely surrounds the port 2|.3 preventing communication therethrough between the upper and lower chambers of housing 20|. The bellows 2|| is urged downwardly by helical spring 2|4 connected to a plate 2|5 secured to the top of the bellows. The plate 2|5 also cooperates with stops 2|6 to limit the compression of bellows 2| I. The engagement of hook 29 on the bellows stem 210 with the arm 2|| on the valve stem' 205 and the sealing of valve member 204 against its seat 205e limits the expansion of the bellows.

The annulus gas is admitted to the lower chamber of valve housing 20| through port 2|8 and acts 'against the interior of bellows 2|| expanding it against the action of the spring 2|4. The spring 2|4 is not strong enough to resist the annulus gas pressure so that the bellows 2| I is normally expanded to its maximum degree with valve 205 closed.

The sealed bellows 205 contains gas under pressure, which pressure is slightly less than the normal annulus gas pressure so that were it not for the locking action of hook 209 against arm 2|| the annulus gas pressure would open valve 204 by compressing bellows 206.

In operation of the system of Figure 15. when suiiicient oil has built up past check valve 12 into the accumulation chamber 20 to fill the accumulation chamber the weight of the oil together with the force of spring 2|4 will be sumcient to overcome the force of the annulus gas on bellows 2I| of the valve 200 and will move the hook 209 downwardly. This leaves the bellows 206 free to compress under the influence of the annulus gas pressure and open valve 204 admitting gas through passage 203 and `conduit 2|2 to the tubing beneath accumulation chamber 20. This will cause a drop in pressure in the annulus causing suincient now of gas in line I6 to actuate dart valve of the surface valve mechanism. The dart valve |05 admits gas to the lower side of diaphragm |02 which pushes upwardly on stem |96 starting clock motor |95. This will turn cam |93 from the rest position shown in Figure to a position where the high part of the cam will press against the upper end of the stem of valve |90 pivoting it about point |9| and opening port 42. This will reduce the pressure transmitted through conduit 34 to the upper surface of diaphragm 32 and allow spring 33 to open motor valve 30. Gas will then be admitted to the casing annulus at a higher rate than it is exhausted through subsurface valve 200 to the tubing so that annulus gas pressure will rise. When the oil rises in the tubing it leaves the valve 200 but is replaced by gas which maintains the bellows 2|I compressed, thereby keeping valve 204 open. The gas pressure will be higher than the hydrostatic pressure of the oil but injury to the bellows is prevented by stops I I6 against which the bellows comes to rest. After a predetermined time clock motor will have driven cam |93 to a position where it permits spring |92 to close valve |90 thus preventing exhaust of air from hollow body l0 through port 42. This will increase the pressure transmitted through conduit 34 to the upper surface of diaphragm 32 and close motor valve 30. The annulus gas pressure will then start to fall. When the annulus gas pressure falls belowthe normal pressure at which the cycle began 'and to a pressure below that within bellows 206 the bellows 206 will expand closing valve 204. It should be noted here that the annulus gas pressure at which valve 204 closes is below that necessary to actuate the surface controls for otherwise the valve would close again before the surface controls were actuated. After valve 204 closes the gas still in the tubing expands, expelling the oil from the top of the well. The drop in gas pressure in the tubing when the oil has been expelled permits the bellows 2|| to expand again thus loclnng valve 204 in closed position. Closure of valve 204 stops the flow of gas in line I6 through valve 30 permitting the dart valve |05 to close, ready for the next cycle of operation. By-pass 60 of the surface valve mechanism permits gas to enter the annulus at a slow rate until the annulus gas pressure returns to the norrrail or starting pressure. The cycle is then comp e e.

Referring to Figure 17 which shows a graph of the pressure time relations in the casing annulus during a cycle, the normal annulus pressure 1s indicated at a. At point b the subsurface valve 200 opens and the gas pressure drops until point c is reached at which the surface gas valve 30 opens. The annulus gas pressure then rises until at point d the surface gas valve 30 closes. The gas pressure then falls to point e at which the subsurface gas valve 200 closes. The annulus is then gradually pressured back up to normal where at point f the by-pass valve of the surface valve mechanism closes.

In Figure 18 there is shown a modified form of the system of Figure 15 which also operates on the second described cycle. The surface valve mechanism is similar to that of Figure 1 in that changes in the annulus pressure are relied upon to both open and close the main surface gas valve. However, because in the second described cycle the annulus pressure drops below normal at the end of the cycle to a pressure lower than that required to actuate the surface controls, a mechanism is provided which causes the surface controls to open and close the main surface gas valve only on every other fall and rise of the annulus gas pressure.

Referring to the drawing there is bellows 259 disposed in a chamber 260 connected by conduit 41 to the gas supply line |6 on the down stream side of the main gas valve 30. The bellows contains adjustable compression spring 26| which tends to expand the bellows, Bellows 259 is connected to one end of stem 262 which is connected at its other end to a leaf spring 26211 whi-ch has upper and lower arms 262b and 262e extending at right angles therefrom and a pin 262d on its extremity.

When bellows 259 reciprocates stem 262 the arms 2621) and 202e of the leaf spring 262a are in position normally to abut against pin 263 formed by an extension of the central pivot of toggle linkage 204 and causes the toggle to travel between an upper position resting against stop 265a and aerea-.osa

atloweinpositioni'restinggagainst stop; 2651). How-w ever; as shownin: Figure 19-at a, onupward travel. Othebellowsstemfsuilicient tocause arm 262C. to

abut against pin.. 263 and -.move l the l toggle upwards, .the,.p in.;262al.y on the extremity of theleaf spring will have passed above pivotedbell crank lever 266:. Lever 266has a limited vtravel clockwise -so that whenpthe'bellows'stem. 262 moves downragain the-pin. 262dislidesdown thetop side of v.lever 266 -carryingtha-leaf spring 2620i .to Athe left; When thepin 2621i islowered past the pivot 'p pointA of .the leverv266 it `slips overto. guidefrail 26T-as shown atb infFigure A19'. Further lowering of'the pin262d permits1itt0 slipV off the .bottom of: guide rail261 vonto guider-ail 268 as shown .at c in-Figure .-19; Upwardl travelof pin2i2d will then follow `guide `railpZEzuntil the pin 26M slips over' theztop of thesguiderail-.Z andyreturns .taits normal line'fof Itravel asshown in Figure i8. All theftimeethepin 2620i is -traveling on guide ,rails 261 and. 268-thefleaf.springfZZa will.be.bent to the left `far enough toA bringthe linefof Atravel-of armss262b and 262C out ofcontact withpin .263. soethat .the toggle .264is not actuated.

In its uppergrest position. .toggle 264 is bent sufficentlyg. so that vthe .rod- 26S connected thereto is out 'ofz contact with :the l'top end of1flapper 'valve |90'fasfshown1in. thedrawing, Figure 18.` In its lowerrest position the toggle 264 is straight so that .rod V2|i$i ismoved through its bearing269a to th'eirighttsuiiicient to open the 'dapper valve |94.

VThe;subsurfaceconstruction: of Figure 18 differs -fromathat of', all thepreceding embodiments or' the4 invention in. .that the: accumulation chamber,` isrof` the same@diametenastherest oftthe tubing,` being `constituted by` that part of 'the tubinsfabbve thefsubsurfaceeasevalve up to theievei inilthetubingto; which the foil. must rise to open thefsubsurfaceigas valve; This construction may beuisedi-wherever` thefbottonfl hole pressure of the oil iszsuiiicientlyhigh: Suchtan arrangement may b'ev a'. positive requiren'ienty where the; diameter of the :hole has been reduced 'to a .point .whereealarge diameter "accumulation chamber cannot be. accommodated; liorexample,A in Figure 18 a liner or lower casingx225' of smaller diameter. tharr the upper :casing I l) .has been :set inside fthe .casingzl infthe lower part of the well hole, beingrsealedzto thezcasingat226.

` Iii .the systernr'o Figureel; sinoetheiaccumulatijonizchamber: isof rtheisamediameter" as thesrest' of thee` tubing; a :removablervalvezoonstructioncan be used even' though the'rvalveis located at the bottom ofthe accumulationchamber: Thevalve istmounted insidel the tubing. inv a slightly `en. largedfsection `22 1 similar; tofthefenlarged :section |,3 I :'offFigure. '7'. Receiver 226=`isfsupported .within the tubingfsection 221 .bymeans' of suitable struts. not shown andthe. interiorof the receiveris in communicationWith` thefexterior ofzthe tubing" A'sfbest shown in .FigureZG the subsurface gas valve1123|3` is disposed'within a housingv 23| which isdividedinto tWochambers by afpartition .232. Thereiisalport`233 inthe'partition 232. Mounted on opposite-'sides'cfthe partition 232 andsurroun'dingrtheiport' 233warefupper bellows 2341and lower; bellows: 235 which.` together. forma; double bellowssimilar tothat used in the constructions of; Figures-7- and 9.- Thefends ofthe Vbellovvsin contact with partition 232. are sealed therewith and 1the- .opposite ends of the bellows. arefv closed. Thetop .of the upper bellows is connected to valve stem..236.oarrying valveA member4 231 which normallyrestsagainst valve seat 236 closing,.passage 239 fbetweent the .uppenchamber oi1housingl 23| i and Atheexterior.` A-.ball and -;cagechecktvalve 240-fmay be 'providedinthe passage` 239 to pre-- ventl low ofiluid. downwardlygin. passage 239. A ltnob 24| which maybevgrasped bya fishing tool is .disposed on the topof the housingf23| bymeans ofstruts 242 which provide aspace forthe pas-.- sagelof fluid beneath the-knobV fromthe passage 239.

Theflower bellows i235 is. connected by stem. 2434 to the-top of sealedbellows 244.v Thebottom of bellows 2.44 is-.secured'tothe'-valve housing. 23| just abovethe:tapered-.bottomportion. The areav of the top of bellowsf244e-isllargerithan ,the-area of the-bottom of bellows'235i preferably-being about;.twice as large: Boththe bellows 244-'and the-double bellows-f234235- contain gas-under pressuref Assumingtheareaof `thetopgot bellows 1 244.v to. be '.twicethe 1 area-of bellows 235 the-in-A ternal pressure of; bellows:V 2ML-should be. some-- what greater than half the-internal pressure of i the double bellows,y the :force exerted upwardlyon stein 243fby bellows -.244.will then begreater 'than the downward forceexerted by5-bellows-.235-and-- thefbellows .235*.vvill beoompr-essed until thefplate.- 245.` secured .to the bottom ofbellows.- 235i-fabuts` against the stops.246. The internalv pressureof. the double-bellows shouldv then beslightly-greaterthan the annulus'gas-pressure.admitted;to the. upper chamber of valve-housing23 Vthrough pas.- sage 2.39.A andv port 241. so that the'valve--member 231 will closefthe gasputletpassagea239.

Theringjshaped seals 248 fand-:249.simi-lar yto the. seals.. |35; |31`vand |38shown inxFiguree'jserve.- both to support the valve-housingf23l within-the. receiver 221' andtto'. divide: they annular: space therebetween-intov an upper. gas lpassage and al lower oil passage; Oil isadmitted. to the lower chamber of valve housing 23| through openings 25| `in' the bottom of the receiver 2281and thence through ports 25|! in thebottom ofthe-valvehousing.y and: ports -252 in `the sidelthereof. Port-s 253pthroughplate254lonA which bellows 244- is mounted provide passages for the-flow of oil so. that solid material will not builduparoundfthebellows 244-but will bew washedaway; Thefseal 249'is abovethelevel of port 252and belowthe level of port 241. The seal 242 is above-thelevel of ports 241 andpipef229.

In operation ofthe system. of Figure-18ml will risel past. the` subsurface valve mechanism 230- into: the-tubing until .a predetermined height hasbeen reached sufficient-.to overcome the vupward force `exerted by, differential bellows 244 against the-lowerA bellows 235; The differential bellows- 244-fwill then-contractand the'lower bellows `235` willexpland. Thisvvill cause adrop `in theY internal pressure of the double bellows 234'- and 235' below the annulus gas pressure which acts on .the outsidefof theY upper bellows 234 causing it to contract and moving valve. member 231 downwardly to openthe-gas passage 239. Gas will then now from the annulus through passage 229, port 241 and passage 239finto the tubing and start to lift the oil. At the same time the pressure in the. tubingwill be increased due to the gas sov that 4differential bellows 244 will be further collapsed. until plate. 255. on, the. topA thereofcomes .to rest against stops 256. Assoon asgas begins.toexhaustfromthe casingthe sur.- ace valve mechanism `comesintooperation... The bellows. 259. will. expand, until the.. arm. 25217 movesthe toggle 264. toits.lower. straight position in which the rod.269.\opens.flapper. valve. |90. thereby reducing the gas pressure transmitted 

